Flexible
solar panel goes where silicon can't
Virginia Tech
Led by Shashank Priya, a team of mechanical and materials
engineers and chemists at Virginia Tech, including post-doctoral researchers
Xiaojia Zheng and Congcong Wu, as well as College of Science chemistry
Professor Robert Moore and Assistant Professor Amanda Morris, is producing
flexible solar panels that can become part of window shades or wallpaper that
will capture light from the sun as well as light from sources inside buildings.
Solar modules less than half-a-millimeter thick are being
created through a screen-printing process using low-temperature titanium oxide
paste as part of a five-layer structure that creates thin, flexible panels
similar to tiles in one's bathroom. These tiles can be combined together to
cover large areas; an individual panel, roughly the size of a person's palm,
provides about 75 milliwatts of power, meaning a panel the size of a standard
sheet of paper could easily recharge a typical smart phone.
Most silicon-based panels can absorb only sunlight, but the
flexible panels are constructed to be able to absorb diffused light, such as
that produced by LED, incandescent, and fluorescent fixtures, according to
Priya, the Robert E. Hord Jr. Professor of Mechanical Engineering in the
College of Engineering.
"There are several elements that make the technology very appealing," said Priya. "First, it can be manufactured easily at low temperature, so the equipment to fabricate the panels is relatively inexpensive and easy to operate. Second, the scalability of being able to create the panels in sheet rolls means you could wallpaper your home in these panels to run everything from your alarm system, to recharging your devices, to powering your LED lights."
The panels, Priya said, can also be made to any design, so they
could become window shades and curtains as well, absorbing sunlight through
windows. "The properties of the panels are such that there are really few
limitations in terms of light source," Priya said. "And the fact that
we are dealing with an emerging technology, means we will be able to expand the
utility of the panels as we go forward."
Currently, the efficiency of the cells is nearly on par with the
heavier, rigid silicon structures, but, Priya said, at panel-level there is
some research required. Still, it is likely the new flexible panels will
overtake their rigid cousins soon.
"Amorphous silicon is a fairly mature technology running at
about 13-15 percent efficiency," he said. "Our panels right now operate
around 10 percent at the panel size. At smaller, less-useful sizes, the
efficiency increases, and so we can see a potential for much greater energy
collection efficiencies."
The flexible panels, as they approach the conversion efficiency
of rigid silicon and glass, can also be incorporated into products that the
older technology cannot compete with -- such as military uniforms and
backpacks, items Priya's lab is working on now with the U.S. Army's
Communications-Electronics Research, Development, and Engineering Center.
By
adding flexible panels to these items, soldiers will become their own
recharging stations, resulting in reduction of the logistical footprint of a
fighting force in the field, as well as the weight each individual soldier must
carry on his or her back.
"Right now we are on the cutting edge of this
technology," Priya said. "Our edge is in the ability to fabricate
large-area modules with high efficiency. We are actively working to integrate
the product with the market and we see a wide variety of uses for the
technology, from clothing to windows, to smart buildings to UAVs to mobile
charging stations."
The work of Priya and his team is detailed in the papers, The
Controlling Mechanism for Potential Loss in CH3NH3PbBr3 Hybrid Solar Cells, published
in the July issue of ACS Energy Letters, and Scaling of the Flexible Dye
Sensitized Solar Cell Module, available online now in the journal Solar Energy
Materials and Solar Cells.
The article will be published in the journal's
December edition.
By creating panels that capture a wide variety of light
wavelengths, Virginia Tech engineers are opening a door to an entirely new area
of light and energy recycling that could make saving energy as easy as hanging
a curtain. Another paper demonstrating the stability of the cells will be
published by ACS Energy Letters later in October under the
title, "Improved Phase Stability of Formamidinium Lead Triiodide
Perovskite by Strain Relaxation."
